Streamflow components and climate change: Lessons learnt and energy implications after hydrological modeling experiences in catchments with a Mediterranean climate

Streamflow components and climate change: Lessons learnt and energy implications after hydrological modeling experiences in catchments with a Mediterranean climate

Sustainable water management should consider climate change effects to ensure its future availability. Hydrological modeling is a supportive tool for this analysis, which has been used in this work to assess the climate change impacts on the water resources of three basins under Mediterranean climat...

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Bibliographic Details
Published in:Energy reports 2023-12, Vol.9, p.277-291
Main Authors: Sánchez-Gómez, Alejandro, Martínez-Pérez, Silvia, Leduc, Sylvain, Sastre-Merlín, Antonio, Molina-Navarro, Eugenio
Format: Article
Language:eng
Subjects:
Climate change
Energy production
Hydrological modeling
Streamflow components
SWAT model
Online Access:Get full text
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Summary:Sustainable water management should consider climate change effects to ensure its future availability. Hydrological modeling is a supportive tool for this analysis, which has been used in this work to assess the climate change impacts on the water resources of three basins under Mediterranean climate (Ompólveda and Salado River basins, in Spain, and Guadalupe River basin, in Mexico). The outcomes of previous climate change scenarios simulation addressed with the Soil and Water Assessment Tool (SWAT) have been compiled, evaluating the impacts on the water balance, and focusing on the streamflow components. The potential implications of these effects on energy production have been discussed. The results point to a streamflow reduction by the end of the century around 50%–60% in the worst scenarios, with varying effects for each of the streamflow components. In the Spanish catchments, where groundwater contribution dominates in baseline conditions, a noticeable decrease of this component is expected (up to -74%), becoming lateral flow the main streamflow component. In the Mexican basin, lateral flow, which is already predominant (69%), will experience the largest absolute decrease, but the highest relative decrease might be experienced by groundwater flow, up to -92%. Absolute variations in the surface component are small and the different ways to simulate the climate change scenarios might hinder their interpretation. This work shows that water resources will be even more scarce in these regions, being especially worrying the groundwater component reduction, which currently maintains the streamflow during dry periods. This situation would limit energy production both from sources that directly use water, such as hydropower, and others that require water for cooling. Higher atmospheric and water temperatures will increase demands for irrigation and for cooling systems. Therefore, competition for water will rise among key sectors, and an accurate planning considering these factors must be a priority. [Display omitted] •The impacts of climate change on streamflow and its components have been assessed.•Streamflow might decrease from 34 to 60% by the end of the 21st century.•Groundwater is expected to be reduced from 74 to 92% in the worst scenario.•Water scarcity will increase due to growing demand and availability decrease.•It will have an undeniable impact in energy production, which demand will increase.
ISSN:2352-4847
2352-4847